Nested strong loader apparatus and method

ABSTRACT

An apparatus and method provides one or more controlled, dynamically loaded, modular, cryptographic fillers. Fillers may be loaded by a single loader, multiple independent loaders, or nested loaders. Loaders may be adapted to load other loaders, within cryptographic controls extant and applicable thereto. Integration into a base executable having one or more slots, minimizes, controls, and links the interface between the fillers and base executables. The filler may itself operate recursively to load another filler in nested operations, whether or not the fillers are in nested relation to one another. An ability of any filler to be loaded may be controlled by the base executable verifying the integrity, authorization, or both for any filler. The base executable may rely on an integrated loader to control loading and linking of fillers and submodules. A policy may limit each module function, access, and potential for modification or substitution. Dynamically loaded modules (loaders, other fillers, and submodules thereof), typically represent a relatively small portion of the overall coding required by the base executable, and may provide strong controls limiting integration by providing access that is nested, layered, or both between modules excluding direct access to or by them from the base executable or supported applications.

RELATED APPLICATIONS

This application is a continuation of U.S. Ser. No. 09/274,532 filed Mar. 23, 1999 now U.S. Pat. No. 6,532,451 which is a Continuation-In-Part of, and claims priority to, U.S. Provisional Patent Application Ser. No. 60/079,133, filed on Mar. 23, 1998, the specifications of which are incorporated herein by reference.

BACKGROUND

1. The Field of the Invention

The present invention relates to cryptographic systems and methodology. More particularly, the present invention relates to novel apparatus systems and the capability of hosting a plurality of individual modularized methods for allowing encrypting applications within a single use application operating on a computer and to separately control the access, use, and authorization of each of the individual encrypting applications.

2. The Background Art

Encryption is a technology dating from ancient times. In modern times, encryption of military communications has been common. However, since the famous “ENIGMA” machine of World War II, cryptography has been used in numerous functions. One of those functions is special purpose software or applications that may be hosted on computers. Hiding underlying algorithms, limiting access, inhibiting reverse engineering, limiting unauthorized use, controlling licensure, and the like may be legitimate uses of cryptography.

Cryptographic Processes

Modern cryptography protects data transmitted over high-speed electronic lines or stored in computer systems. There are two principal objectives: secrecy, to prevent the unauthorized disclosure of data, and integrity (or authenticity), to prevent the unauthorized modification of data. The process of disguising plaintext data in such a way as to hide its substance is encryption, and the encrypted result is cyphertext. The process of turning cyphertext back into plaintext is decryption.

A cryptographic algorithm, also called a cipher, is the computational function used to perform encryption and/or decryption. Both encryption and decryption are controlled by a cryptographic key or keys. In modern cryptography, all of the security of cryptographic algorithms is based in the key or keys and depends not at all on keeping any details of the algorithms secret.

There are two general types of key-based cryptographic algorithms: symmetric and public-key. Symmetric algorithms (also called secret-key algorithms) are algorithms where the encryption key can be calculated from the decryption key and vice versa (and in fact these keys are usually the same). These require that a sender and receiver agree on these keys before they can protect their communications using encryption. The security of these algorithms rests in the key, and divulging the key allows anyone to encrypt and decrypt data or messages with it.

In public-key algorithms (also called asymmetric algorithms), the keys used for encryption and decryption different from each other in such a way that at least one key computationally infeasible to determine from the other. To ensure secrecy of data or communications, only the decryption key need be kept private, and the encryption key can thus be made public without danger of encrypted data being decipherable by anyone other than the holder of the private decryption key. Conversely, to ensure integrity of data or communications, only the encryption key need be kept private, and a holder of a publicly-exposed decryption key can be assured that any ciphertext that decrypts into meaningful plaintext using this key could only have been encrypted by the holder of the corresponding private key, thus precluding any tampering or corruption of the ciphertext after its encryption.

Most public-key cryptographic algorithms can be used to provide only one of secrecy or integrity but not the other; some algorithms can provide either one but not both. Only the RSA (Rivest, Shamir, and Adleman) public-key algorithm (U.S. Pat. No. 4,405,829), whose security is based on the difficulty of factoring large numbers, has been able to be used to provide both secrecy and integrity.

A private key and a public key may be thought of as functionally reciprocal. Thus, whatever a possessor of one key of a key pair can do, a possessor of the other key of the key pair can undo. The result is that pairwise, secret, protected communication may be available without an exchange of keys. Thus, in general, a receiver, in possession of its own private key may be enabled to use its own copy of a sender's public key, to decrypt data encrypted with a sender s private key corresponding to the sender s public key.

An asymmetric algorithm assumes that public keys are well publicized in an integrity-secure manner. A sender (user of a public key associated with a receiver) can then know that the public key is valid, effective, and untampered with. One way to ensure integrity of data packets is to run data through a cryptographic algorithm. A cryptographic hash algorithm may encrypt and compress selected data. Such hash algorithms are commercially available. For example, the message digest 5 (MD 5), and the message digest 4 (MD 4) are commercially available software packages or applications for such functions.

A certificate may be thought of as a data structure containing information or data representing information, associated with assurance of integrity and/or privacy of encrypted data. A certificate binds an identity of a holder to a public key of that holder, and may be signed by a certifying authority. A signature is sometimes spoken of as binding an identity of a holder to a public key in a certificate. As a practical matter, a certificate may be very valuable in determining some level of confidence in keys associated with encryption. That is, just how “good” is an encryption in terms of privacy and integrity? That confidence level may be established by means of a certificate hierarchy. By certificate hierarchy is meant a certification process or series of processes for providing certificates from a trusted authority to another creator of keys.

A certificate, being a data structure, may contain, for example, data regarding the identity of the entity being certified as the holder of the key associated with the certificate, the key held (typically it is a public key), the identity (typically self-authenticating) of the certifying authority issuing the certificate to the holder, and a digital signature, protecting the integrity of the contents of the certificate. A digital signature may typically be based on the private key of the certifying authority issuing the certificate to the holder. Thus, any entity to whom the certificate is asserted may verify the signature corresponding to the private key of the certifying authority.

In general, a signature of a certifying authority is a digital signature. The digital signature associated with a certificate enables a holder of the certificate, and one to whom the certificate is asserted as authority of the holder, to use the signature of the certifying authority to verify that nothing in the certificate has been modified. This verification is accomplished using the certificate authority s public key. This is a means to verify the integrity and authenticity of the certificate and of the public key in the certificate.

Cryptographic Policies

Government authorities throughout the world have interests in controlling the use of cryptographic algorithms and keys. Many nations have specific policies directed to creation use, import, and export of cryptographic devices and software. Numerous policies may exist within a single government. Moreover, these policies are undergoing constant change periodically.

Cryptographic policies may limit markets. For example, a cryptographic algorithm may not be included in software shipped to a country having laws restricting its importation. On the other hand, such a cryptographic device may be desired, highly marketable, and demanded by the market in another country. Thus, generalized software development standardization of software, and the like may become difficult for software vendors. Moreover, users have difficulties attendant with supporting limited installed bases of specialized software. That is, a sufficient installed base is required to assure adequate software.

In short, cryptographic use policies sometimes constrain the set of cryptographic algorithms that may be used in a software system. In addition to restrictions on allowable algorithms, cryptographic use policies may also place constraints on the use and strength keys associated with those algorithms. Software shipped or used in any country must be in compliance with the policies extant.

Another common aspect of certain cryptographic use policies is a requirement that a copy of cryptographic keys be stored or “escrowed” with an appropriate authority. However the mechanisms necessary to satisfy different policies can vary greatly.

Cryptography, especially public key cryptography, provides certain benefits to software designers. U.S. Pat. No. 4,200,700, U.S. Pat. No. 4,218,582, and U.S. Pat. No. 4,405,829 are directed to such technology and are incorporated herein by reference. These benefits are available in situations where data may be shared. Many modem software packages (applications, operating systems, executables) are used in businesses or in other networks where multiple “clients” may share a network, data, applications, and the like. Most modern software packages employ cryptography in some form.

One application for cryptography in network management or network operating systems includes authentication. Also, integrity of data packets transferred, encryption of files, encoding associated with licenses for software or servers, and license distribution or serving are some of the applications for cryptography.

Users may be identified and their rights to access may be authenticated by means of passwords on a network. Cryptography is typically used to transfer some authentication, integrity, verification, or the like in a secure manner across a network that may be open to channel tapping. Public key cryptography is typically used in such a circumstance. Another application of cryptography for authentication involves a single sign-on. For example, a user may need to enter a single password at the beginning of a session. This may remain true regardless of the number of servers that may eventually be called into service by the individual user (client) during this single session. Historically, scripts have been used to provide a single sign-on, but public key mechanisms are now being provided for this function.

Users have previously demonstrated that networks may be subject to attack by spoofing of network control packets. This procedure may be demonstrated in playback and in man-in-the-middle scenarios. By such spoofing, users may obtain unauthorized privileges on a network server. Adding packet signatures, keyed on a per-session basis may provide improved packet integrity.

File encryption is becoming more available. Such encryption has particular use in the special circumstance of audit files. For example, a need exists to protect an audit trail from inspection or modification, or both, by a system administrator, even though the audit trail remains under the system administrator's physical control.

Certain licensing schemes may use various encryption modes to protect software against piracy by end users and others throughout a distribution chain. Data structures cryptography methodologies, checks, and other protection mechanisms may be proprietary to a software developer. Nevertheless, license server mechanisms are being developed to support control of the use of application software in conformity with licenses. Licenses may be provided by an application software provider. The license server may use public key cryptography to create and verify signed data structures. Secret key cryptography may be used to support authentication and file encryption.

Certain applications may provide file confidentiality using proprietary, exportable, secret key algorithms. Users in large numbers make use of such algorithms. Nevertheless, considerable interest in breaking such proprietary algorithms has been successful with certain software. Proprietary encryption methodologies have been consistently broken, given enough time and attention by interested hackers.

Certain applications use public key cryptography for digital signatures. Market leaders in software have provided relatively weak secret key algorithms adopted by others. Thus, files written in different applications from different vendors, even encrypted files, may be opened by an application from any of the vendors using the market leader s secret key algorithm. Within a single product line, a vendor of software applications may use multiple algorithms. Several, if not a plethora of, algorithms exist, including both secret key algorithms and public key algorithms. Stream and block ciphers, as well as hash functions are available and well documented in the computer programming art. Also, certain algorithms are the subject of patent applications which may cloud their broadly based use.

What is needed is a standardized cryptography methodology for distribution across entire product lines. Moreover, encryption technologies are needed for permitting a licensee of a principal software manufacturer to become a third party vendor or value-added distributor capable of producing its own proprietary software, software additions, or preplanned software modules. Currently, software-with-a-hole may provide an operating system with a cryptographic module that fits in the “hole” in an operating system. However, software manufacturers using this technology typically require that a third-party vendor send its product to the principal software manufacturer for integration. The manufacturer may then provide all interfacing and wrapping of the third-party s filler (such as an encryption engine) to fit within the “hole” in the software of the manufacturer.

Also, export restrictions exist for encryption technology. Limiting the strength of exported cryptography is established by statute. To be exportable, such products must meet certain criteria (primarily limitations on key size) that effectively prevent the exportation of strong cryptographic mechanisms usable for data confidentiality. Moreover creating “cryptography with a hole” is undesirable for several reasons, including export and import restrictions. Cryptography with a hole is the presence of components specifically designed or modified to allow introduction of arbitrary cryptographic mechanisms by end users. A great escalation of the difficulty of such introduction, without creating numerous, individually customized software packages, is a major need today, although not necessarily well recognized.

Certain foreign countries have more stringent regulation of the importation of encryption technology by non-government entities. A government may require that any imported encryption technology be subject to certain governmental policies as well as key escrow by some governmental agency. Key escrow systems may be easily provided in software, but integrity and assurance remain difficult. Using only software, reliable key escrow may be impossible, in the absence of very high assurance. For example, Class B3 or A1 may be required of a “trusted computing base” in order to protect keys against disclosure or modification. Likewise, protection of algorithms against disclosure or modification, and escrow against bypass, are also often required. Under any circumstances, software offers few protections when compared with hardware solutions.

Customers, whether third-party vendors, distributors, or end users, need information security. International commercial markets need products that may be marketed internationally without a host of special revisions that must be tracked, updated, and maintained with forward and backward compatibility as to upgrades and the like. Meanwhile such solutions as key escrow do not receive ready customer acceptance in U.S. markets, particularly where a government is an escrow agent. Furthermore, individual customers or vendors may wish to operate individualized cryptography systems or other authenticable applications in conjunction with a single operating system or host application. Currently, no provision exists for allowing such customization in a controlled, authenticable environment.

Therefore, what is needed is a cryptography apparatus and method that may be mass produced in a variety of products across an entire product line. A technology, or product that can be sold in identical form both domestically and abroad is highly desirable. An encryption method and apparatus are needed that may provide improved methods for security and integrity of data provided by cryptographic algorithms and keys themselves, without requiring “trust” between sender and receiver.

Also needed is a key escrow mechanism for corporate environments. For example, file encryption by an employee will usually be required to be subject to an escrow key in the possession of the employer. Also, in conjunction with signature authorities, delegation of such authority may be useful in a corporate environment. Nevertheless, each corporate user may be viewed as a secondary (vendor) level desiring to have its own encryption and escrow control of all copies of all keys.

What is needed is a method for producing cryptographic applications that may be customized individually, from individual modules. That is, what is needed are modules that may be used to limit the capabilities of cryptographic applications without proliferating individual customized software products that may become very difficult to maintain, upgrade, support, and the like. What is needed is an apparatus and method that can separate a cryptography application or a cryptography filler for an operating system “slot” into modules. Modules need to be configured to minimize the extent of interfaces and the amount of code that must be interfaced. Modules should minimize the number of exclusions from a system that must be patched or replaced in order to enable the software system to satisfy relevant cryptography usage policies.

What is needed also are an apparatus and method effective to enable a manufacturer of a cryptographic engine to produce a single implementation of a modular package embodying particular cryptographic algorithms. The manufacturer should remain able to include that implementation in all versions of a software product. This should be true regardless of different key usage policies mandated by various regulatory authorities. It should be true regardless of a requirement for disabling of certain of the included algorithms.

Also needed is an alternative to prior art systems that require both a “policy” and an algorithm implementation to be supplied (even lastly shipped) from the manufacturer of a cryptography engine as the wrapping and certifying entity. Instead, what is needed is an apparatus having an architecture and implementation by which a manufacturer of a cryptographic engine need not be the same entity as a supplier/generator of a policy (e.g., government) to which the cryptographic engine s algorithms are constrained to conform.

Beneficial, and therefore desirable or needed, is an apparatus and method having distinct executable modules and policy data structures sufficiently separable to reduce the cost of customizing an entire software system. Thus, a system is needed that is adaptable to inexpensive customization without implementing an embedded policy.

Also needed is an apparatus and method for separating a policy from an algorithm to enable flexibility in the management and delivery of cryptographic capabilities in conformance with the local regulations. For example, some method is needed by which a manufacturer can produce a cryptographic engine, but exclude a policy certificate permitting use of the algorithms implemented by that engine. That is, a method is needed by which a manufacturer or one or more other policy certificate authorities may separately offer key and policy authorization, certification, and verification conforming to local regulations.

Further need exists for an apparatus and method whereby a plurality of dynamically linked cryptographic modules might be hosted within a single base application. Accordingly, the dynamically inked cryptographic modules might be separately accessed, authorized, and used, and might operate independently of each other. Such a need exists whereby the individual dynamically linked cryptographic modules, singly, or as a whole might be absent from the base application without significantly limiting the operation of the base application.

BRIEF SUMMARY AND OBJECTS OF THE INVENTION

In view of the foregoing, it is a primary object of the present invention to provide an apparatus and method by which a plurality of individual and distinct modular cryptography modules might be hosted by a single base application operating on a computer.

It is another object of the invention to provide such an apparatus and method by which the plurality of individual and distinct modular cryptography modules might be separately loaded into individual slots within the host program.

It is another object of the invention to provide an apparatus and method for dynamic loading of the plurality of individual and distinct modular cryptography modules into the base executable in a manner to prevent substitution, modification, extension, or misuse of algorithms implementable by the modules and whereby each of the independent slots may have independent mechanisms for authorization of the modular cryptography modules.

It is another object of the invention to provide such an apparatus and method whereby the modules act as fillers for the slots and whereby modules filling separate slots might act independently and transparently from each other.

It is another object of the invention to provide such an apparatus and method whereby the presence or absence of a particular module within any of the slots does not prevent the proper operation of the base program.

It is another object of the invention to provide such an apparatus and method whereby the plurality of slots might be serviced by a single loader or individual loaders, and whereby the slots might be recursively constrained with inner slots located inside of outer slots and each slot being provided with an independent loader capable of authorization and linking.

Consistent with the foregoing objects, and in accordance with the invention as embodied and broadly described herein, an apparatus and method are disclosed in certain embodiments of the present invention as including a controlled modular cryptography system.

A principle feature provided by an apparatus and method in accordance with the invention includes limitation of software integration. For example, a software integration limiter may provide a cryptographic operating system with a “slot.” That is, an operating system may be thought of as a block of executable instructions storable in a memory device, and loadable on a processor. An additional feature under the invention is that a plurality of such slots might exist within a given base application, such as network operating systems for example. The individual slots may be filled by different applications or components of applications, such as distinct types of cryptography systems or cryptography systems having different functions, or cryptography systems by different customers or vendors.

Furthermore, the various slots may have differing mechanisms for authenticating and linking the different applications loadable therein. For instance, each slot may use a separate public or private key for authentication purposes.

The individual slots may be serviced by a single loader, or each may have its own loader. Furthermore, the individual slots may be recursively loadable, with certain of the slots operating within others of the slots.

The software integration limiter in accordance with the invention may provide an architecture and coding to limit the integration of modular application allowed to fill these slots. Thus, the operating system or other base application cannot operate at all, or may be configured to not operate with cryptographic capability, absent an authorized, added software “filler” filling each of the slots.

Another feature available in an apparatus and method in accordance with the invention may be a vendor-constrained, remotely sealed, software integration limiter. For example, prior art systems may require that a manufacturer receive, license for import, and wrap the code of value-added resellers and vendors, incorporating the codes into a cryptographically enabled software product.

By contrast, an apparatus and method in accordance with the invention may provide for a universal “base executable” comprising a software system for operating on a computer. A software development kit may be provided with certain authorizations to an agent, vendor, distributor, or partner. The authorizations may be provided as certificates permitting the agent to create software modules and wrap them without their contents being known, even to the original manufacturer of the “base executable” or the software development kit. Such a system may then include a constrained policy obtained by the agent, vendor, etc., in cooperation with a government, to meet the import laws of the country of sale of the entire package, the software “base executable” modules from vendors, and an authorizing policy. Such a system may allow an agent (development partner, third party value-added seller, module vendor, distributor) to provide sealed encryption algorithms. The algorithms may remain known only to the agent, (partner, distributor, etc.) although accessed for linking using keys authorized by the manufacturer of the base executable.

The software development kit may provide for an authorization mechanism, such as a certificate of authority immediately identified with the software development kit and the agent. Any “base executable” may then verify any module from any vendor to determine that the vendor has produced a module in accordance with policy constraints imposed on the software development kit and verified by the “base executable” produced by the manufacturer.

Thus, a universal “base executable” may be exportable by a manufacturer and importable by a distributor or reseller. A distributor may be responsible to obtain the proper licensure for cryptographic equipment and functionality. The “base executable” can verify that all modules operating within a slot to which the particular authorization module is assigned come from a software development kit assigned to a vendor operating within prescribed bounds of policy authorization and other permitted functionality.

In short, the “base executable” knows how to recognize a valid signature provided from a module created on a proper software development kit. A software development kit may produce or generate proper digital signatures. The agent's, distributor's, or partner's module product may then carry the proper signature. Therefore, the “base executable” may recognize and run only those modules having valid signatures corresponding to software development kit “toolboxes” of known, authorized agents or distributors, and in accordance with authorized policies. The base executables may be different for each slot and each base executable may recognize only certain digital signatures.

Another feature of an apparatus and method in accordance with the invention may be a null engine. A null engine may be provided by a manufacturer with any “base executable” (principal software product, operating system), having no enabled cryptographic capability. Nevertheless, the null engine may support all interfaces required by a “slot” in the base executable, and all functionalities except cryptographic capabilities required by a “filler.” Thus, for example, an operable software system may be delivered having no cryptographic capability, simply by providing a filler including a null engine to fill the “slot” within the software product (operating system, base executable) provided by the manufacturer. Thus, where only certain of the slots are available for use by a particular customer, the slots that are not available may be filled by null engines.

Another feature of the apparatus and method in accordance with the invention may be flexible key escrow capability. This feature may be thought of as a modular key escrow method. Escrow capability may escalate from a self escrow. For example, an individual company, individual user, or the like, may hold and control all keys. At an opposite extreme an escrow of a key may reside with some other independently authorized escrow agent. A key escrow may reside with a governmental agency itself as required in some countries.

Another feature of an apparatus and method in accordance with the invention may include cryptographic wrapping of keys. That is, wrapping may be thought of as tamper proofing (authentication) and encrypting (secrecy protection) a key. Prior art systems' keys may be simply bit strings of sufficient length and complexity to reduce the probability of their being deciphered.

Here, a holder's identification and a certification authority's identification may be applied to a key itself. The digital signature of the certifying authority may enable verification of such certification. The keys may be centrally managed, such as by a management module in the “base executable” from a manufacturer. Such a module can therefore restrict creation, distribution, and use of keys, especially within a network or internetwork.

Another feature of an apparatus and method in accordance with the invention may include quality-graded certificates. The certificates may be generated by distributors (value-added resellers, module vendors, agents, partners). However, the certificates may provide a “pedigree” indicating an integrity level of the cryptography provided by a certificated software product. Thus, a purchaser of software who will become a user or owner (holder) may know the cryptographic strength (algorithm, key length) or quality (integrity, value limit of assurance) of the systems used or created, with a verification that cannot be forged.

Another feature of an apparatus and method in accordance with the invention may be provision of cryptographic engines that are not independently usable. For example, cryptographic engines may be comprised of, or included with, wrapped, non-linkable modules that can only be used in a filler to fill a “slot” in a base executable (principal software application) from a specified manufacturer.

Thus, unlike the prior art where a cryptographic engine obtained by a vendor or third party may be used with any software, cryptographic engines made in accordance with the invention may not be enabled absent verification of their integrity, applicability, policy, or the like by a base executable (principal software product). A separate slot or software instruction limiter operating within a loader within a slot may verify any and all modules attempting to link with the base executable through the slot and vice versa. Different types of modular applications and cryptography systems may be enabled through different slots.

Another feature of an apparatus and method in accordance with the invention may be constraining the linking of modules to a specific class of module, or within a specific class of module, through the use of cryptography. Thus, for example, a hierarchy of linking may be created within individual software modules, so that all modules may link only to peers (associated modules in one filler) and may not necessarily be able to link directly with selected modules of the total group of peer modules with the same filler. For example, an application or library module may not bypass a limiting manager module to interface with a cryptographic engine module.

Another feature of an apparatus and method in accordance with the invention may include a restriction of the use of cryptography, by use of cryptographic methods. Thus, for example, a manufacturer may produce a library of cryptographic functions that is much stronger than what would ordinarily be exportable under the laws of the United States, or importable under the laws of receiving countries.

For example, if only a 40-bit engine may be exported under normal circumstances, a library may be created in which a digital encryption standard using 64 bits exists within the library. Nevertheless, the more powerful standard may not be implemented, absent the proper keys which are themselves encrypted and maintained under the control of the manufacturers and the policies provided.

Thus, the above objects may be met by one or more embodiments of an apparatus and method in accordance with the invention. Likewise, one or more embodiments of an apparatus and method in accordance with the invention may provide the desirable features as described.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other objects and features of the present invention will become more fully apparent from the following description and appended claims, taken in conjunction with the accompanying drawings. Understanding that these drawings depict only typical embodiments of the invention and are, therefore, not to be considered limiting of its scope, the invention will be described with additional specificity and detail through use of the accompanying drawings in which:

FIG. 1 is a schematic block diagram of modules arranged in one embodiment of an architecture for an apparatus and method in accordance with the invention;

FIG. 2 is a schematic block diagram of an apparatus in a network for hosting and implementing the embodiment of FIG. 1;

FIG. 3 is a schematic block diagram of an example of executables operable in a processor for implementing the embodiment of the invention illustrated in FIG. 1;

FIG. 4 is a schematic block diagram illustrating examples of data structures in memory device corresponding to the apparatus of FIGS. 1-3;

FIG. 5 is a schematic block diagram illustrating certificate hierarchies for implementing one embodiment of an apparatus and method in accordance with the invention; and

FIG. 6 is a schematic block diagram of certain operational processes for one embodiment of a controlled modular cryptography system implemented in accordance with the invention.

FIG. 7 is a schematic block diagram illustrating a recursive arrangement of slots in accordance with the invention.

FIG. 8 is a schematic block diagram illustrating alternative arrangements for including a plurality of slots in a base application.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

It will be readily understood that the components of the present invention, as generally described and illustrated in the Figures herein, could be arranged and designed in a wide variety of different configurations. Thus, the following more detailed description of the embodiments of the system and method of the present invention, as represented in FIGS. 1 through 6, is not intended to limit the scope of the invention, as claimed, but it is merely representative of certain presently preferred embodiments of the invention.

The presently preferred embodiments of the invention will be best understood by reference to the drawings, wherein like parts are designated by like numerals throughout. Reference numerals having trailing letters may be used to represent specific individual items (e.g., instantiations) of a generic item associated with the reference numeral. Thus, a number 156 a, for example, may be the same generic item as number 156 f, but may result from a different version, instantiation, or the like. Any or all such items may be referred to by the reference numeral 156.

Referring to FIGS. 1-3, a method and apparatus for providing controlled modular cryptography is illustrated in software modules supporting hardware, and as executables distributed through a processor. Reference is next made to FIGS. 4-6, which illustrate in more detail, schematic block diagrams of certain preferred embodiments of an apparatus and method for implementing controlled modular cryptography in accordance with the invention.

Those of ordinary skill in the art will, of course, appreciate that various modifications to the detailed schematic diagram of FIGS. 1-6 may easily be made without departing from the essential characteristics of the invention as described. Thus, the following description of the detailed schematic diagrams of FIGS. 1-6 is intended only as an example, and it simply illustrates certain presently preferred embodiments of an apparatus and method consistent with the invention as claimed herein.

Referring now to FIGS. 1-6, a controlled modular cryptography (CMC) process 12 or method 12 may be implemented using a plurality of modules 13. The CMC process 12, alternately referred to herein as CMC 12, may be embedded within another executable 14, such as a network operating system 14. The network operating system 14 may include an operating system proper 15, what would conventionally be known in a generic operating system as the operating system 15.

The operating system 14 may also have provision for insertion of a pre-processor 92 in a conventional hole 93.

By contrast, the CMC 12 is not accessible by third parties at a pre-processor slot 93. Third parties may create pre-processors 92 having direct access to the operating system 15. Prior art cryptographic engines are often mere pre-processors interposed between applications 40 and the operating system 15. Likewise, the unauthorized installation by a third party of a cryptographic engine in a pre-processor slot 93 may be rendered virtually impossible by the CMC 12 and operating system 15. Instead, the CMC 12 may be loaded into the base executable 14 such as the operating system 14 in a manner that embeds the CMC 12 into the operating system 14 and prevents interfacing by any third party to the cryptographic capability of the CMC 12. (See FIG. 3.)

Referring now to FIGS. 1-6, and more particularly to FIG. 1, the controlled modular cryptography 12 may include library modules 16 for interfacing with applications 40. Each library module 16 (X library 16, or simply library 16) may be application-specific.

The loader 90 (see FIG. 3) provides layering (hierarchical linking) or nesting (recursive loading or linking) of interfaces. The layering may effectively prevent applications 40 and an operating system proper 15, for example, from interfacing directly with controlling modules 13 (e.g., manager modules 18) or with engines 20 (e.g., cryptographic engine 50). The loader 90 may do this directly by dynamic loading of modules 13, enforcing restrictions on access to interfaces between levels 16, 18, 20, 22, 15 illustrated in FIG. 1.

Manager modules 18 as well as the original loader 90 loading a filler 12 (CMC 12) may assure that a layering hierarchy is enforced between modules to limit interfaces. Manager modules 18 may interface with library modules 16. The manager modules 18 may also interface with the cryptographic engines 20, or engine modules 20. Support modules 22 may interface with engine modules 20 also.

Library modules 16, manager modules 18, and support modules 22 may interface with the operating system 15 in one preferred embodiment of an apparatus and method in accordance with the invention. The engines 20 may be enabled to interface only with other modules 13 , and not with the operating system 15.

The subdivision of modules 13 in a layering architecture (e.g., layer 18 is manager modules 18 including modules 42, 44, 46) great flexibility may be obtained. Since modules 13 are dynamically bound by the loader 90, and managed by a manager module 18, the modules 13 may be modified or exchanged as needed and as authorized. Management modules 18 not yet envisioned may be added in the future, without revising the base executable 14, or even the filler 12, outside the module 13 in question.

For example, a management module 18 may support cryptographic-token PIN (personal identification number) management, not available in an initially purchased product 14. Another example may be added support for policy management enhancements, such as providing separate APIs (application programming interfaces) for encrypting and decrypting ubiquitous financial data used by banks.

New functionality, not typically used or required in current practice by banks, may include a separate key type or size specifically for financial data. Such keys 156, 160 may be relatively stronger than general keys 156, 160, while use, holders, data types, and the like may be restricted by policies 164 crafted for special financial purposes. Thus financial keys 156, 160 may be managed differently from other general types of keys 156, 160.

Referring now to FIG. 2, a network 56 may comprise a plurality of nodes 58 (e.g., clients 58). Although the clients 58 a, 58 b, 58 c are illustrated, the computers of the clients 58, server 62, and router 64 may also be thought of as being hosted, programmed to run on any computer 58, 60, 62, 64 on a network 56. Likewise, the CMC 12 may be programmed into any of those computers 58, 60, 62, 64. By node is meant a computer on a network 56 in its broadest sense.

Likewise, the host 60 or server 60 may actually be programmed to function as one of several servers 62 or routers 64. As a practical matter, the server 62 may be replaced by the server 60. A node 58 may include some or all of the structural contents illustrated for the server 60. For example, if every node 58 comprises a computer, every node 58 may have any or all of the components 70-86.

A network 56 may include a backbone 66 for interconnecting all the nodes 58 or clients 58. The router 64 may also connect to one or more other networks 68. The network 68 may be a local area network (LAN), wide area network (WAN) or any size of internetwork.

The server 60 may include a CPU 70 or processor 70 for hosting the operating system 14 and CMC 12. As a practical matter, a random access memory 72, or RAM 72, may temporarily store, in part or in total, any or all codes and data associated with executables within the CMC 12. For example, during operation of the CMC 12, individual modules 13 might be stored, or a portion thereof might be stored in the RAM 72.

The CPU 70 and RAM 72 may be connected by a bus 74. Also on the bus may be operably connected a network card 76 or network interface circuit 76 (net card 76), one or more input devices 78, and output devices 80, or the like. Additional memory devices such as a read-only memory 82 (ROM 82) and a storage device 84 (such as a hard disk 84), may be operably connected to the bus 74 to communicate data with the processor 70.

Additional ports 86 may be provided as appropriate. As a practical matter, the input device 78 and output device 80 may merely represent ports for accessing one or more available input or output devices 78, 80. Similarly, with the distributed nature of hardware and software in a modern computing environment, other devices may be accessed, through the net card 76, elsewhere on the network 56.

Referring to FIG. 1 once more, the interfacing between modules 13 may be restricted. Such a restriction may provide additional assurance that the CMC 12 may not be misused, modified, or replaced improperly. Therefore, certain of the modules 13 may have operating system interfaces 24. For example, the interfaces 24 a, 24 b, 24 c represent the interfaces between the libraries 16, managers 18, base 22, respectively, shared with the operating system 15.

In the illustrated embodiment of FIG. 1, the engines 20 share no interface with the operating system 15. Instead, the engines 20 may interface through the base support 22. Library interface 26 represents the interface between library 16 and applications 40. The library interface 26 may be considered to be an interface between the CMC 12 and applications 40.

The libraries 16 may be structured to interface directly with applications 40. The foundation 54 or the CMC foundation 54 may be thought of as the core of the CMC 12. The managers 18 provide cryptographic facility as well as controlling access to and between modules 13, especially in the core 12. The interface between the CMC enforcement by the foundation 54 and applications outside the base executable 14 is moved away from the manager interface 28 by the library interface 26 and interposed libraries 16. Thus applications 40 are not permitted to interface directly with the (controlling) management modules 18. This further avoids creation of cryptography with a hole.

The manager interface 28 represents the interface between the manager modules and the library modules 16. The engine interface 30 represents the interface between engines 20 and the manager modules 18. The support interface 32 represents the interface between the engines 20 and the support modules 22.

In general, communications 38 may be calls from upper layers 40, 16, 18, 20 shown to lower layers 16, 18, 20, 22, respectively, in FIG. 1. Each layer 16, 18, 20, 22 may properly execute without requiring anything from a layer 18, 20, 22, 15, respectively, below.

For example, in one embodiment of an apparatus and method in accordance with the invention, one library 16 may be an audit library 34. For example, the audit library 34 may have functional responsibility for encrypting security audit data for storage. The underlying data may correspond to events of significance to audit executables. The network 56 itself may be managed by an individual acting as a system manager, yet the audit data encrypted by the audit library 34 may be inaccessible to the system manager.

Other libraries 36 may be provided. Each of the libraries 36 may be application specific. In one presently preferred embodiment, each of the applications 40 interfacing at the library interface 26 may have an associated, unique, library module 36 provided.

The key generation manager 42 may create symmetric keys or asymmetric key pairs provided to cryptographic engines 20. The key generation manager 42 may also perform the escrow function of the escrow archive 170 (see FIG. 6). A base manager 44 may provide enforcement of policies 164.

Access to modules 13, such as the engines 20, and access to cryptographic algorithms within engine modules 20, and the like, may be enforced by the manager modules 18. In one embodiment of an apparatus and method in accordance with the invention, the base manager 44 may provide an enforcement function with respect to all functions and all modules 13. Other managers 46 may also be provided. For example, manager modules 46 may alter methods of policy enforcement for the escrow of keys 156.

In one embodiment, the CMC 12 may be provided with a null engine 48. A null engine 48 may be operated to interface at the engine interface 30 and the support interface 32 while providing no enablement of cryptographic capability. Thus a base executable 14 may be fully functional otherwise, including all necessary interfaces to the filler 12 (CMC 12), while having no enabled cryptographic capability. The interfaces 26, 24 to the filler 12 may be as secure as if the dynamically loaded modules were manufactured as integrated portions of the base executable 14.

Thus, an apparatus 10 may be provided as a base executable 14, having fully imbedded support for a cryptographic engine 20. However, the presence of a null engine 48 accommodates all the proper interfaces 30, 32 while actually providing no cryptographic capability.

Thus, a CMC 12 (filler 12) may be provided with a base executable 14, including a null engine 48, exhibiting minimal differences with respect to the operating system 15 as compared to another cryptographically-enabled product. Meanwhile, other engines 50 may be provided by a manufacturer or a third party vendor authorized to create cryptographic engines 20 according to some policy and authorization.

A base support module 52 may provide some minimal set of operating system instructions for the engines 20. That is, in general, the engines 20 need some access to the operating system. Nevertheless, for providing the assurance that engines 20 may not be created, modified, extended, circumvented, inserted, or the like, in an unauthorized fashion, the support module 52 may intervene. Thus, the base module 52 may provide access to some limited number of functions from the operating system 15 for the engine 20.

Referring now to FIG. 3, an operating system 14 may be implemented in one embodiment of an apparatus and method in accordance with the invention to include a loader 90. The loader 90 may be associated with the operating system proper 15. The functional responsibility of the loader 90 may be to dynamically load and properly link all modules into the CMC 12 (filler 12), for example, installing (e.g., embedding) them into the operating system 14.

More specifically, the loader 90 may be tasked with the functional responsibility to provide all proper linking between modules 13. Linking may be enabled on a layer-to-layer (or interface 28, 30, 32) basis rather than on a moduleby-module basis. For example, a binding may exist between any two modules 13 in a layer (e.g., layer 18, or layer of manager modules 18). Binding may also exist between any module (e.g., modules 42, 44, 46) in that layer (e.g., layer of managers 18) and another module (e.g., modules 48, 50) in a layer (e.g., layer 20, or layer of engines 20) sharing an interface (e.g., interface 30) with that layer (e.g., layer 18).

Specific modules 13 need not be individually limited and controlled by the loader 90. In one embodiment, individual modules 13 may be bound (linked). Thus, for example, only those functional features authorized for a key generation manager 42, or a cryptographic engine 50, might be enabled by being properly bound.

In one example, a cryptographic engine 50 may be manufactured to contain numerous algorithms. However, according to some policy 164 (see e.g., FIGS. 5, 6) incorporated into a certificate 154, a manager 46 and the loader 90 may limit linking (binding) to an enablement of algorithms and engines 20. A manager module 46 may also control key usage, including length and function. Function may be distinguished between, for example, encryption versus authentication. Use may be controlled based upon, for example, a manufacturer's (of the module 13) signature 162 and key type.

The operating system 15 may support a selection of pre-processors 92 such as the audit event filter 92. Pre-processors may be adaptable to fit in a hole 93 readily available for the purpose. In one currently preferred embodiment of an apparatus and method in accordance with the invention, a CMC 12 is not adaptable to be implemented as a preprocessor 92. Instead, the CMC 12 may be limited to interfacing only with the operating system proper 15 as illustrated in FIG. 1, and only after proper loading by a loader 90. Even within the operating system 15, the CMC 12 may be limited to interfacing with the operating system 15 through a limited number of interfaces 24.

As a practical matter, certain applications 94 or programs 94 have resident portions within the server 60 hosting the operating system 14. For example, a file system 98, a name service 100, a work station 102 and the like may have resident portions operating in the processor 70. Even if, for example, a server 62 is operating as a file server, the file system 98 may be a portion of a file server executable that needs to be resident within the processor 70 of the server 60 in order for the server 60 to communicate with the server 62 over the network 66.

Generally, certain data may need to flow into and out of the operating system 14. Accordingly, a number of channels 96 or data flow paths 96 may need to exist. As a practical matter, the channels 96 may be comprised of either paths, data itself, or as executables hosted on the processor 70 for the purpose of providing communication. Thus, an audit file 104, an accounting log 106, an archive file 108, and the like may be provided as channels 96 for communication.

Thus, the overall operating system 14 along with the applications 94 and channels 96 may be thought of as a local system 110 or the local processes 110. These local processes 110 operate within the CPU 70. The CPU 70 is a processor within the server 60 or host 60. As a practical matter, the processor 70 may be more than a single processor 70. The processor 70 may also be a single processor operating multiple threads under some multitasking operating system 15.

Data representing executables or information may be stored in a memory device 72, 82, 84. Referring now to FIG. 4, one may think of a dynamic data structure 114 or an operating system data structure 114 storable in an operable memory 116. That is, for example, the operating memory 116 may be within the RAM 72 of the host 60. All or part of the data structure 114 may be moved in and out of the processor 70 for support of execution of executables.

The data structure 114 may be dynamic. The modules 13 for example, may be dynamically loadable, such as network loadable modules. Thus, for example, a host 60 may operate without having any fixed, storable, data structure 114. That is, no static data structure need be assembled and stored in a manner that may make it vulnerable to being copied or otherwise inappropriately accessed. The data structure 114 may only exist dynamically during operation of the processor 70, and even then need not all exist in the memory device 116 (e.g., RAM 72) simultaneously at any time. Thus, additional assurance is provided against misuse, and abuse of data and executables in a CMC 12 associated with an operating system 14.

The data structure 114 may contain a certificate 118 and certificate 120. A certificate 118, for the purposes of FIG. 4, may be thought of as an instantiation of a certificate 154 associated with the operating system 14 and its included CMC 12. The certificate 118 may be thought of as the data certifying the holder of a certificate operating and using the data structure 116. By certificate 120 is meant data provided in a certificate issued to the holder.

A certificate 118, 120 may also be thought of as a binding of a holder ID 122, 132 to a public key 126, 136, certified by a digital signature 124, 134 of a certifying authority. An issuer (e.g., 152 b) or authority and a holder (e.g., 152 d) may each be a holder (e.g., 152 b) to a higher authority (e.g., 152 a), and issuer (e.g., 152 d) to a lower holder (e.g., 152 h), respectively.

When discussing authorities, holders, receivers, and the like, it is important to realize that such an authority, holder, sender, receiver, or the like may actually be a hardware device or a software operation being executed by a hardware device. Any hardware device, operating software, or data structure in a memory device may be owned, controlled, operated, or otherwise associated with an individual or an entity. Nevertheless, insofar as the invention is concerned, names of such entities may be used to represent the hardware, software, data structures, and the like controlled or otherwise associated with such entities.

As a practical matter, a certificate 118 authenticating the rights of the CMC 12 may contain an identification record 122 identifying the holder (the specific instance of the CMC 12), a signature record 124 verifying the higher certification authority upon which the holder depends, and a public key record 126 representing the public key of the holder. The private key 128 may be very carefully controlled within the CMC foundation 54 using encryption for wrapping. The private key 128 may be associated with the holder (CMC 12) and is the private half 128 of a key pair including the public key 126. Thus, by means of the private key 128, the holder may create the signature 134 in the certificate 120 for another use of the key pair 136, 138.

Meanwhile, a certification authority 152 (see FIGS. 5-6) may provide to a holder or sign 166, the certificate 118 (one of the certificates 154). The certificate 120 may reside in another computer or simply be allocated to a different thread or process than that of the certificate 118.

As a practical matter, a private key 128, 138 may be protected by physical security. Therefore, a private key 128, 138 may typically be controlled and be cryptographically wrapped except when dynamically loaded into a dynamic data structure 114.

The private key 128 may be used to certify an identification record 132 identifying a new holder. A signature 134 created by use of the private key 128 may verify the authenticity and quality of the certificate 120 and public key 136. The public key 136 may be thought as the matching key 136 to a key pair including the private key 138 created by the new holder of the certificate 120. That is, one may think of a new holder, as a process, or an individual issuing a public key 136 certified by the signature 134 of the private key 128 as duly authorized to create software which functions within the limits of a policy 140. The certificate 118, an instance of a certificate 154 held by the CMC 12, may have a signature 124 by a higher certifying authority 152.

A policy 130, 140 may limit the authorization of the holder identified by the ID 122, 132 and certified by the digital signature 124, 134. A policy 130, 140 may incorporate the limitations governing the use of algorithms in engines 20, for example. Thus, a policy 130, 140 may be thought of, for example, as the rules enforced by a manager module 18 controlling access to and from a module 13, such as an engine (e.g., cryptographic engine 50).

Each policy 164 (e.g., 164 d, see FIG. 5) may contain a digital signature 163 (e.g., 163 d) of the certifying authority 152 (e.g., 152 b) above the holder 152 (e.g., 152 d) of the certificate 154 (e.g., 154 d) and policy 164 (e.g., 164 d). The policy 164 (e.g., 164 d) may thus be bound to the corresponding certificate 154 (e.g., 154 d) by the digital signature 163 d.

In one embodiment, policies 164 may be generated by a separate policy authority using a policy authority digital signature 129, 139 (see FIG. 4). A policy authority signature 129, 139 binding a policy 130, 140 to a certificate 118, 120 need not be different from a certificate authority signature 124, 134, but may be. This is analogous to the certification authorities 152 for certificates 154. Thus, the policies 164 may be provided and signed 166 by a certifying signature 163 binding the policy 164 to a corresponding certificate 154. Nevertheless, the policy 164 may be certified by a policy authority 129, 139 other than the certificate authority 152 creating the corresponding certificate 154.

Referring to FIGS. 4-6, the certificate 118 may include identification records 122. The identification records 122 may contain information recursively identifying the higher certifying authority (e.g., 152 a, 152 b), as well as the holder (CMC 12) certified. However, the signature 124 may be verified by using the public key of the higher authority 152. For example, the signature records 124 may comprise a signature of a signature root authority 152 b or higher authority 152 a certifying, which authority is known by the identification 133. The private key 128 may be thought of as a key by which the holder (e.g., the CMC 12) creates signatures 134 for certificates 120 associated with, for example the key generation module 42 of the base executable 14 (see FIG. 6).

The identification records 132 may typically identify the holder of the certificate 154 associated with the certificate 120. Although the signature 134 is associated with the certifying authority providing the certificate 120, and itself holding the certificate 118 identification records 133 may identify the certifying authority 152 (e.g., associated with the ID 122). The signature 134 may be used by entities or processes needing to verify the authorization of the holder (entity identified by the ID 132) of the certificate 120.

As a practical matter, a private key 128, 138 is typically not stored in the clear in any non-volatile storage generally available. That is, a private key 128, 138 may typically be unwrapped or loaded only dynamically to minimize the chance of any unauthorized access. The private key 128, 138 may optionally be stored within a cryptographic co-processor, for example an additional processor 70. The cryptographic co-processor may be embodied as a chip, a token, a PCMCIA card, a smart card, or the like. The private key 128 may be unwrapped in the co-processor for use only within the co-processor.

The applications 40, the preprocessor 93, and the channels 96 may be stored in the data structure 114. Nevertheless, the data structure 114 may be distributed.

The library modules 16, the manager modules 18, the engines 20, and the support modules 22 may be stored in the data structure 114. In one embodiment, the data structure 114 may all be resident in the RAM 72 in some dynamic fashion during operation of the operating system 14 functioning in the processor 70.

The certificate 120 may be embodied as illustrated in the frames 142. The identification record 132 may be thought of as a data segment 132 associated with a holder. The segment 133 may be provided to identify a certifying authority 152. Each public key 136, 126 may be represented as bits of a segment 136, 126 in the frame 142. The signature 134, 124 of a certifying authority 152 may be represented as another set of bits of a segment 134, 124 in the frame 142. The policy 140, 130 may be represented by another segment 140, 130. The certificates 118, 120 may have corresponding (e.g., even identical) policies 130, 140 under which to operate.

The public key 136, 126 is identified with the holder ID 132, 122. A public key 136 126 is typically published to other functions or to other entities, just as a certification authority s 152 a, 152 b, 152 c public key 160 a, 160 b 160 c is published. Thus, a certifying authority's public key 136, 126 is illustrated in FIG. 4 as being separate from the frame 142. The public key 136, 126 may be embedded in another certificate held by a certifying authority. Similarly, a holder's private key 138, 128 may be maintained with utmost security. Therefore a holder's private key 138, 128 is not available with the holder's published public key 136, 126, except to the holder. Thus, a holder's private key 138, 128 may not actually be generally available or associated with the certificate 120, or certificate 118, respectively, in the frame 142.

Referring now to FIGS. 4-6, the certificate hierarchy is illustrated, as is the implementation of operational keys 156, 160. Reference numerals having trailing letters, may be thought of as specific examples of a generic structure or function associated with the reference numeral alone. Thus, a certifier or certification authority 152 is a general expression, whereas the root certifier 152 a and the CMC signature root 152 b are specific examples of a certification authority 152.

In general, an authority 152 (e.g., root certifier 152 a), may issue a certificate 154 (e.g., 154 b, 154 c). A certificate 154 (e.g., 154 b, 154 c) may be associated with authorization of a certificate holder (e.g., 152 b, 152 c) by a certification authority 152 (or just authority 152). Associated with a certificate 154 may be certain data 120, 118. For example, in one embodiment, a certificate 154 may actually be embodied as a frame 142 as illustrated in FIG. 4.

In general, a certificate 154 (e.g., 154 b) may be prepared by an authority 152 (e.g., 152 a) using a private key 156 (e.g., 156 a) held securely in the possession of the authority 152 (e.g., 152 a). A certificate 154 (e.g., 154 b), itself, may contain information such as the holder identification 158 identifying the holder to whom the authority 152 has issued the certificate 154. Note that the holder 152 (e.g., 152 b) may itself be another authority 152 (e.g., 152 b) to a lower level holder 152 (e.g., 152 d).

The certificate 154 may also include the authority's 152 signature 162. By signature 162 is meant, a digital signature as known in the cryptographic art. Also included in the certificate 154, or linked by the signature 162 with the corresponding certificate 154, may be a policy 164. A policy 164 represents the extent of the authorization provided by the certificate 154 (e.g., 154 a) to the holder (e.g., 154 b) of the certificate from the authority (e.g., 152 a) in order to produce cryptographic functionality.

For example, a holder 152 d may have a certificate 154 d and private key 156 d authorizing the holder 152 d to produce modules, such as cryptographic engines 20, manager modules 18, library modules 16, or symmetric or asymmetric keys 156. The policy 164 d may embody the restrictions, limitations, and authorizations extended to the holder 152 d of the certificate 154 d.

In one embodiment, the enforcement of policies 164 may be managed in one or more of several, relatively sophisticated ways. For example, a policy 164 might permit a private key of a relatively long length, such as 1024 bits, to be used for digital signatures 162 only. On the other hand, a private key 156 used to wrap symmetric keys may be permitted to extend only to 768 bits, and only on condition that the key 156 be escrowed.

Also, rules for “composition” of policies 164 (certificated features or functions), or perhaps more descriptively, “superposition” of policies 164, may be embodied in manager modules 18. For example, more than a single policy may be loaded within a filler 12, for one of several reasons. For example, modules 13 from different vendors may be manufactured under different authorities 152. Also by way of example, as in FIG. 4, a policy authority digital signature 129, 139, certifying a respective policy 130, 140, need not be from the same source as a certificate authority digital signature 124, 134, but may be.

Meanwhile, a manager module 18 may be programmed to enforce the most restrictive intersection of all features (e.g., certificated features or functions such as quality, cryptographic strength, etc.). For example, one policy 164 (a certificated feature) may require that key-wrapping keys may be 1024 bits long and must be escrowed. Another policy 164 in another module 13 in the same filler 12 may require that keys be only 512 bits long, but need not be escrowed. The cryptographic manager module 18 may require a key length limit of 512 bits, and require escrow also. Thus a superposition of policies 164 may use the most restrictive intersection of policy limitations.

An authority 152, thus certifies 166 or provides a signing operation 166 for a certificate 154 for a holder. Referring to FIG. 5, the certification authority 152 a (the root certifier 152 a) is an authority 152, to the CMC signature root 152 b as a holder, both with respect to the certificate 154 b.

Each certificate 154 is signed using a private key 156 of a certifying authority 152. For example, the certifiers 152 a, 152 b, 152 e use private keys 156 a, 156 b, 156 e, respectively, to sign the certificates 154 b and 154 e delivered to the CMC signature root 152 b and server CA 152 e, and certificate 154 j forwarded by the key generation module 42.

The certificate 154 b also includes a public key 160 b. A public key 160, in general, is one half of a key pair including a private key 156. For example, the private 156 a, 156 b, 156 c, 156 d, 156 e, 156 f, 156 g, 156 h is the matched half associated with the public 160 a, 160 b, 160 c, 160 d, 160 e, 160 f, 160 g, 160 h. The key pair 156 a, 160 a, is associated with the root certifier 152 a. Similarly, the private key 156 b may be used by the CMC signature root 152 b to certify 166 d, 166 e the certificates 154 d, 154 e with the signatures 162 d, 162 e. Thus, in turn, each of the public keys 160 d, 160 e, respectively, is the public key half of the pair that includes the private key 156 d, 156 e, respectively.

A holder, such as the module signature authority 152 d or the server certification authority 152 e may verify the validity of the public key 160 b using the signature 162 b and the public key 160 a. Similarly, a processor entity may verify the validity of the certificates 154 d, 154 e, respectively, by recourse to the signature 162 d, 162 e, respectively and the publicly available public key 160 b responsible.

Referring to FIGS. 5 and 6, generation of private/public key pairs 156, 160 and subsequent certification 166 may be represented by cascading certificates 154. For example at the top or root of all certification authorities 152 may be a root certifier 152 a. The certifier 152 a may generate a private 156 a, and a public key 160 a, as a key pair 156, 160.

The root certifier 152 a need have no signature 162. The root certifier 152 a in such circumstance must be “trusted.” Another method, other than a digital signature 162 of a higher certifying authority 152, may typically be required for verifying the public key 160 a of the root certifier 152 a.

Only one root certifier 152 a (RC 152 a) is needed for the entire world. In one embodiment, the root certifier 152 a may be an entity willing and able to credibly assume liability for the integrity of public keys 160, and the integrity of associated certificates 154. For example, an insurer, or a company known and trusted by the entire business world, may serve as a root certifier 152 a. Such companies may include large, multinational insurance companies and banks. The root certifier 152 a is functionally responsible to physically protect the secret key 156 a. The root certifier 152 a is also responsible to distribute the public key 160 a.

The root certifier 152 a may authorize private/public key pairs 156 b, 160 b to be created by the CMC signature root 152 b. The integrity of the public key 160 b, and the identity 158 b of the CMC signature root may be certified by a digital signature 162 b created by the root certifier 152 a using the private key 156 a.

Any subsequent entity, receiving a certificate 154 cascading from the CMC signature root 152 b as a certifying authority 152, may verify the certificate 154. For example, the certificate 154 b,and its contents (public key 160 b, ID 158 b, and signature 162 b) may be verified using the signature 162 b. The signature 162 b may be created using the private key 156 a. Therefore, the signature 162 b can be verified using the public key 160 a, available to the entity to whom the authority of a certificate 154 b is asserted as authentication.

The root certifier 152 a may have its public key 160 a embedded in the base executable 14. Alternatively, any method making the public key 160 a securely available may be used. In this example, the base executable 14 or principal software product 14 may typically, be an operating system 14. The base executable 14, operating system 14 or base executable 14 may be thought of as including everything that arrives in the base executable associated with newly purchased, generic, software package 14. This may sometimes be referred to as “the base executable 14.”

As a practical approach, the CMC signature root 152 b may be associated with, and the private key 156 b be in the possession of, the “manufacturer.” For example, the manufacturer of a base executable 14, such as a network operating system 14, may be the holder of the private key 156 b used to certify all public keys 160 d and associated certificates 154 d of the module signature authority 152.

As a practical matter, the highest level of public key 160 embedded in (or otherwise securely available to) a base executable 14 may be the signature root key 160 b associated with the certificate 154 b. An instantiation of the certificate 154 b may be embedded in, or otherwise securely available to, the CMC loader 90. Thus, the loader 90 may verify against the manufacturer s public key 160 b (available to the loader) the signature 162 d in the certificate 154 d effectively presented by the module 13. That is, one may think of the certificate 154 d as being included in the cryptographic module 13 (engine 20) of FIG. 6 by a module vendor.

Thus, the loader 90 may verify that a vendor is authorized to produce the modules under the policy 164 d bound to the certificate 154 d. However, the foregoing starts at the wrong end of the process. The signature 168 on the module 13 is present for verification of the module by the loader 90. The signature 168, encrypted using the private key 156 h, may be verified by recourse to (e.g., decryption using) the public key 160 h. The key 160 h presented in the certificate 154 h, also available with the module 13.

In turn, the signature 162 h on the certificate 154 h, may be verified using the public key 160 d. The key 160 d corresponds to the private key 156 d used to encrypt the signature 162 h. The key 160 d is available in the certificate 154 d with the module 13. The certificate 154 d and key 160 d are verified by the signature 162 d on the certificate 154 d with the module. The signature 162 d may be verified (e.g., such as by decryption or other means) using the public key 160 b of the CMC signature root 152 b. An instantiation of this key 160 b is available to the loader 90 with the certificate 154 d, as discussed above. By having the certificate 154 d independently of the modules 13, the loader may thus verify each module before loading into the filler 12 (CMC 12).

As an example, the CMC signature root 152 b may be associated with the manufacturer of the base executable 14. The base executable 14 may be thought of as the principal software product 14, such as an operating system 14. By contrast, the CMC 12 may be thought of as a filler 12, a modularized segment that is required to be present within the base executable 14, but which may be modified, customized, limited, authorized, or the like by a manufacturer for a class of customers or by a suitably authorized, third-party vendor of modules.

In the case of a base executable 14 that serves as a network operating system 14, such as Novell Netware™, the manufacturer (Novell, in this example) may be the CMC signature root 152 b. Another example may be a third-party vendor of modules 13. A third party vendor of modules 13 may produce, for example, engine modules 20 for insertion into the CMC 12, but may be a value-added reseller of the base executable 14 adapted with such a cryptographic engine module 20 or other module 13.

For purposes of discussion, a manufacturer may be thought of as the maker of the base executable 14. A vendor or third party vendor may be thought of as the maker of modules 13 for inclusion in the CMC 12 (filler 12) portion of the base executable 14. A distributor, reseller, or third party reseller may be thought of as a seller of base executables 14 purchased from a manufacturer. The manufacturer may distribute and create modules 13. A vendor of modules 13 may be a distributor of the base executable 14, also.

Thus, a situation of great interest involves a manufacturer desiring to provide the base executable 14, while certifying a vendor s module products 13. The modules 13 may be integrated as part of the CMC 12 of the base executable 14 after the base executable 14 is shipped from the manufacturer. As discussed above, shipment of a base executable 14 in some standard configuration is desirable. In a preferred embodiment a base executable 14 shipped into a foreign country having import restrictions on cryptography, may provide a reliable method for enabling authorized cryptography exactly, while disabling all other potential uses of cryptography. Minimum modification, interfacing, and cost may be provided by an apparatus and method in accordance with the invention, with maximum assurance of authorization and control, all at a reasonable processing speed.

The CMC signature root 152 b may be responsible for manufacturing and exporting the base executable 14 to customers (users) and third party resellers, and supporting software development kits (SDKs) to third party vendors. The manufacturer may be a maker modules 13 also. Typically, the manufacturer may produce the null engine 48, at least.

The module signature authority 152 d associated with the ID 158 d may be that of the holder of a software development kit for modules 13. A policy 164 d bound to the certificate 154 d may be certified by the signature 162 d of the CMC signature root's 152 b private key 156 b.

The policy 164 d may be enforced by the manager module 42 and embodies the limits on the use and strength of keys 156 d. For example, the length (strength) of keys 156 useable under the policy 164 d and the types of modules 13 may be controlled by statute in each country of importation for the base executable 14.

A loader 90 from the manufacturer may control linking of modules 13. Thus, a third party, including a module vendor cannot change the limitations inherent in a key, the policy, or the like.

A policy 164, in general, may define the maximum strength of the key. A module signature authority 152 d, holding a particular authorized software development kit may create different types of keys 156 as long as each is within the bounds of the policy 164 d. The module signature authority 152 d may also then certify a module-signing key pair 152 h authority for each module type produced and sold. Certificate 154 h, so signed using the private key 156 d, may provide a key 156 h to sign each module 13, such as the cryptographic modules 13 exemplified by the engine 20 of FIG. 6. Meanwhile, a module signature authority 152 d may certify embedded keys 160 h and associated certificates 154 h automatically by using the software development kit.

Note that a chain or cascade of certificates 154 d, 154 h may be used in a module in order to have the signatures 162 for the loader 90 to verify. The loader 90 may then verify the keys 160 d, 160 h using signatures 162 d, 162 h of the certificates 154 d, 154 h to authorize the loading of the module 20 (see FIG. 6).

Verification may be necessary in order for the loader to have the certified keys 160 d, 160 h, 160 b necessary for verifying the module signature 168. That is, a vendor may use a software development kit containing a module signature authority 152 d to create some number of module signing key pairs 152 h.

The private keys 156 h may be used to sign 166 m with a signature 168 every module 13 created. Note that the modules 16, 10, 42 in the base executable 14 of FIG. 6 may all be thought of generically as modules 13 as in FIG. 1. The certificate hierarchy 154 h, 154 d, 154 b of the module 13 may all be verified by the loader 90 using the appropriate public keys 160 d, 160 b, to verify the respective signatures 162 h, 162 d from the certificates 154 h, 154 d.

The server certifying authority 152 e (CA 152 e) may be produced by the manufacturer based on a CMC signature root 152. The server certificate authority 152 e may be embodied in the server 60 (see FIGS. 2 6) on a server-by-server basis. Thus, a server 60 may generate keys 156 j or pairs as shown in FIG. 6. Thus, the server 60 is able to certify by a key generation manager 42 keys 160 generated by that server 60.

A private key 156 may preferably be unique to an individual server 60 so that there is no need to provide a globally exposed private key 156. The private key 156 e of the server certificate authority 152 e of FIG. 6 may be the only private key 156 embedded in a base executable 14 or operating system 14 hosted by a server 60. This may be very important for providing signatures 162 j for certifying 166 j other keys 160 j and IDs 158 j signatures 162.

As a practical matter, by embedding is meant alternate methods that may be implemented in the server 60 in another manner well adapted to dynamic loading. For example, the private key 156 e may not necessarily need to be embedded, as in the illustrated example. Rather, the key 156 e may simply be “securely available” such as by reading from a secure hardware device. Thus, a key 156 e may be securely available to the CMC 12 in the server 60 and function as well as if actually embedded. The expression embedded should be interpreted broadly enough to include this “securely available” approach. This is particularly true since dynamic loading in combination with cryptographic techniques herein for verification make such methods readily tractable.

In general, a private key 156 may be used to produce certifying signatures 162. A key 156 may also be used to decrypt data received when it has been encrypted using a corresponding public key 160 to ensure privacy.

Both keys 156, 160 may be necessary for both privacy and integrity, but they are used at opposite ends of a communication. That is, for example, the CMC signature root 152 b may use the public key 160 of the module signature authority to assure privacy communication to the module signature authority 152 d. The module signature authority 152 d, may use the public key 160 b of the CMC signature root 152 b. Each 152 b, 152 d may use its own private key 156 b, 156 d to decrypt received messages. Integrity may be verified by a signature 162 authored using an appropriate private key 156 b, 156 d. Meanwhile authenticity of communications, such as a signature 162 d, created using a private key 156 b may be verified by an entity using the corresponding, published, public key 160 b.

As a matter of good cryptographic practice, integrity and confidentiality (privacy) may rely on separate keys. A module 13 may employ a plurality of private/public key pairs 156/160. One pair may be used for channel confidentiality. A separate and distinct pair may be used for channel integrity.

The certificates 154 in the base executable 14, for example in the module 13, and loader 90 illustrate authentication of the cascade of certificates. Initially, the modules 13 of FIG. 6 are signed by the signature 168 created with the private key 156 h.

The public key 160 h may be used to verify the signature 168. References to decryption of signatures 168 mean verification, which requires some amount of decryption.

The authenticity of the public key 160 h is assured by the signature 162 h on the certificate 154 h. The signature 162 h is verified using the public key 160 d in the certificate 154 d available.

The authenticity of the public key 160 d is assured by the signature 162 d on the certificate 154 d. The signature 162 d is verified using the public key 160 b in the certificate 154 b available.

This illustrates the practical limit to authentication. The following is not separately illustrated in the architecture, but could be implemented. The authenticity of the public key 160 b could be assured by the signature 162 b by obtaining the certificate 154 b. The signature 162 b would have to be verified using the public key 160 a in the certificate 154 a available. Note that some other mechanism must be used to verify the certificate 154 a.

A server may generate keys for cryptographic operations. For example, a separate set of keys 156 j may exist for each client 58 on the network 56.

Asymmetric systems are more computationally expensive than symmetric systems. The key length used in asymmetric systems is typically much longer than that for symmetric systems (e.g., asymmetric keys may be 1-2 k bits long, versus 40, 64, or 128 bits for typical symmetric keys). In cryptographic protection schemes, an asymmetric algorithm may used to protect a symmetric key that will be distributed to a client 50 encrypted using the client's public key 160 and decrypted by the client's corresponding private key 156. A shared secret key may be used for shared symmetric key communication in a network 56. Thus, the server CA private key 156 e may be used to generate a signature certifying other public/private key pairs 160, 156. That pair 156, 160 may be used to certify another pair or to distribute a symmetric key pair.

A certificate 154 is needed for a public key 160, and must be signed (162) using the corresponding private key 156. A private key 156, for example, is used to certify any public key 160 created in the key generation module 42 of FIG. 6. That is, the key generation module 42 may generate a key pair 156, 160; in which the server CA private key 156 e is used to sign the certificate 154 j created by the key generation module for the cryptographic libraries. The server CA private key 156 may be used to sign all certificates 154 (with included public key 160) generated by the CMC filler 12 in the base executable 14 of operating system 14 hosted on the server 60.

A server key (not shown), which may be symmetric, may be generated by the key generation module 42 and used for key wrapping. All keys that should be kept secret may be wrapped for being transmitted or stored secretly outside of the CMC 12, such as in a cryptographic library 36.

Certain of the attributes of a key 156 (algorithm, archive, type, etc.) may be wrapped along with the key 156 before being passed outside of the CMC 12. Thus a private half of an asymmetric key pair, or a symmetric, secret key should be wrapped preceding any export or output from the CMC 12.

The libraries 16 may be (typically must be) application-specific, and anything transmitted to them may be considered to be outside of the control of the CMC 12 once it is transmitted to the library 16.

Escrow is controlled by a manager 14 such as the key generation manager 42, a cryptographic manager 18. In any case, every key 156 j generated should be saved throughout its useful life. A key 156 j may be saved, typically, in an encrypted format in a secure environment called a key archive 170. The archived key 156 j may first be encrypted, and the key 160 to that encryption is the escrow public key 160 k. The corresponding public key 160 j is also archived, although it may be publicly available.

The escrow authority 152 f may be an entity generating a public/private key pair 160, 156 for each server 60 in order to encrypt (privacy protect) private keys 156 before archival. Thus, the escrow authority 152 f may have a private key 156 f unique to itself, which is used to sign 162 k the certificates 154 k for all of those public/private key pairs 156 k, 160 k. The escrow authority 152 f may receive its private/public key pair 156 f, 160 f from a key escrow root 152 c. The key escrow root key 156 c may certify the key 160 f held by the escrow authority 152 f. The manufacturer of the base executable 14, (Novell, in the example above), may be (i.e., control) the key escrow root 152 c.

The certificate 154 c held by the key escrow root 152 c may itself be signed by the root certifier 152 a certifying the public key pair 160 c of the key escrow root 152 c. Thus, the key escrow path (certifications 166, cascade) of certificates 154 and keys 156, 160 may have its source in the root certifier 152 a, just as the CMC signature root 152 b does.

An escrow authority 152 f may hold the private key 156 f to the archive holding the encrypted, escrowed keys 156. The archive 170 may actually be inside the server 60. Thus, the holder of the base executable 14 has all the encrypted keys 156.

However, a government or some such agency may require certain keys of the escrow authority 152 f. A manufacturer such as Novell, the operating system manufacturer, in the example above, could also serve this function as well as being the key escrow root 152 c. This may be advantageous for the same reasons that a manufacturer would be the signature root 152 b. The escrow authority 152 f may give to the agent the escrow private key 156 f for the specific server. This may be the private half 156 k of an escrow key 156 that the keys 156 in question were encrypted in for archiving. The government may then go to the user of the server 60 to get access to the archive 170 in the server 60 of the owner of all the keys 156 j.

Some governments may want to be the escrow authority 152 f for all escrow keys. The government may unlock the key archive 170 whenever desired. In certain countries, the key archive 170 may be in possession of a trusted third party or the government. For example, the key generation module 42 may need to create keys 156 j, encrypt them, and send them as data to a trusted third party acting for the government to control the archive 170.

From the above discussion, it will be appreciated that the present invention provides controlled modular cryptography in an executable designed to be embedded within another executable such as a network operating system, or the like. Cryptographic capability is controlled by a manager module operating according to a policy limiting the capability and access of other modules, particularly that of the cryptographic engine. Thus, a system 14 (a base executable 14) may be provided having nearly all of the capabilities of the “filler” 12 intact. A very limited interface between a filler 12 and its internal engine selection 20 provides for examination of engines 20 by regulatory authority. Moreover, the restricted interfaces 30, 32 between the engines 20 and the remaining modules 13 of the filler 12 present great difficulty to those who would modify, circumvent, or replace any portion of the filler 12 (CMC 12) in an attempt to alter its capabilities. Meanwhile, asymmetric key technology provides for enforcement of all controls, thus providing privacy and integrity for all communications, operations, exchanging of keys, and the like.

Referring to FIG. 7, an operating system 15 may include a loader 90 in an apparatus 10. The loader 90 may be one of several nested loaders 300. For example, the loader 90 controls access to a location 302 as described above. Modules 304 may be loaded dynamically by the loader 90. If no cryptographic capability is to be included in any module 304, a null engine 48 may be installed in the place of the module 304. Additionally, any of the modules 13 (see FIG. 1) may be loaded as the module 304, as permitted in any of the architectural options described above. Thus, a module 304 may actually include the entire base executable base 14 of a filler 12 in the entire hierarchical arrangement provided.

In the embodiment of FIG. 7, a nested loader 306 is preferably loaded by the loader 90. Accordingly, a third party, properly authorized, as described above, may provide a loader 306 to be loaded into the location 302 by the loader 90. The loader 306 may be authorized by proper certificates 154, keys 156, and policies 164 to be properly loaded and linked by the loader 90. Thus, any module 304, 308, or the like may also be an entire hierarchical system 14 of modules 13.

Also, a loader 310, properly verified, loaded, and dynamically linked into the location 302, may include therein modules 312, which might in turn comprise another loader 314. Thus, not only may multiple loaders 306, 310 be loaded into the location 302 by a principal loader 90, but the loader 310, may also be adapted to load other loaders 314. Thus, the loader 314 may recursively implement the properly authorized, verified and controlled operations corresponding to those performed by the loader 90, within the domain defined and allocated to the loader 314. That is, the loader 314 may not supplant nor circumvent the loader 90. Rather, the loader 314 is loaded, linked, and controlled in accordance with the authorizations verified by the loader 90 and implemented thereby. Likewise, the loader 314 may simply be a module 304 of an entire hierarchy 14 of modules 13 (See FIG. 1). Thus a more restrictive environment provided by an extant policy 130, 140 may be implemented in a module 316 than in higher-level modules such as the module 304.

Thus, FIG. 7 illustrates nested loading of multiple modules 304, 308 which are independent from one another, and concurrently, loading of other modules 312, 316 recursively. Since the controls implemented by the filler 12 in the operating system 15 may be recursively applied, differing levels of security may be imposed between modules 302, 308 312, and 316 within the apparatus 10. Typically, greatest security imposed will by within the recursion 90, 310, 314.

Referring to FIG. 8, an operating system 15 may have multiple loaders 90, 320 integrated with the operating system 15. In one embodiment, the loaders 90, 320 may be “visible” to one another. Alternatively, the loaders 90, 320 may be completely independent and transparent of one another.

One embodiment, dynamically linked molecules 318, 322 may not be “aware” of each other s existence. In an alternative embodiment, a link 324 may be established dynamically between the modules 318, 322. Because the loaders 90, 320 operate dynamically according to the infrastructure provided as described above for FIGS. 1-6, security and control may be assured. As a practical matter, multiple loaders 90, 320, aware of one another or not, create no new risk not already accommodated. One may see that the modules 318, 322 represent a multiplicity of linked filler modules 12 of the basic embodiment 14.

Thus, relative interdependence or independence of the modules 318, 322 is a matter of design choice. Similarly, what may be done with an individual module 13, 304, 308, 312, 316, 318, 322 may be done with any number of modules as described above. Accordingly, multiple sets of hierarchies 14 of modules 13, recursive loading of loaders 306, 314 by loaders, 90, 310, respectively, and loading by plurality of loaders 90, 320, may all be encompassed within selected embodiments of an apparatus 10 in accordance with the invention.

Moreover, the loader 90 may be independent of another loader 330 having a separate slot 332 associated therewith. Accordingly, the loader 330 may load a module 334 into the slot 332. As discussed above, the module 334 may actually implement multiple modules 13. Additionally, the module 334 may itself include nesting, recursion, and other processes. In the depicted embodiment of the FIG. 8, the loaders 90, 330 are typically transparent to one another. Thus, the slot 332, serviced by the loader 330, and the slot 336, serviced by the loader 90 are not available or visible to the opposing loaders 90, 330, respectively. Furthermore, each of the loaders 330 may have separate authorization mechanisms, for example, each may have a separate public or private key or digital signature associated therewith the public keys associated with the different loaders 90, 330 can be the subject of different distribution channels.

Thus, multiple slots 302, 330, 336 serviced by one or more loaders 90, 320, 330, may be controlled as described above to provide a broad spectrum of flexible, yet highly controllable, dynamically integrated executables and data.

The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative, and not restrictive. The scope of the invention is, therefore indicated by the appended claims, rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope. 

1. A method to limit software module integration, comprising: receiving a first filler module having a first unique property; dynamically loading the first filler module into a base module using the first loader after the first unique property is verified by the first loader, wherein the base module when loaded with the first filler module permits the first filler module to be executed; processing a second loader of the first filler module; and dynamically loading a second filler module after the second loader verifies a second unique property of a second filler module, wherein the second filler module when loaded is capable of being executed, and wherein the first and second loaders are independent loaders from one another.
 2. The method of claim 1 wherein in receiving, the base module includes a plurality of slots for integrating the first and second filler modules with the base module after the first unique property and the second unique property are verified.
 3. The method of claim 1 wherein in receiving, the base module is an operating system processing on one or more processors.
 4. The method of claim 1 wherein in dynamically loading the first and second filler modules, the filler modules are modules wrapped with cryptographic information that identifies the first and second unique properties.
 5. The method of claim 4 wherein in dynamically loading the first and second filler modules, the cryptographic information defines access rights to and/or interaction rights between the first and second filler modules with the first and second unique properties.
 6. The method of claim 1 wherein in dynamically loading the second filler module, the second loader dynamically links a plurality of addition modules of the second filler module to one another in a layered hierarchy.
 7. The method of claim 1 wherein in dynamically loading the first and second filler modules, the first and second unique properties are associated with access policies.
 8. A method to verify software module integration, comprising: identifying a first unique property of a first filler module; verifying the first unique property before permitting the first filler module to load before subsequent processing; authorizing the first filler module to process when verified and loaded, and wherein the first filler module acquires a second unique property of a second filler module; verifying the second unique property by the first filler module before permitting the second filler module to load before subsequent processing; and authorizing the second filler module for processing when it is verified and loaded, and wherein the first filler module is loaded with an independent loader that is different from a loader that loads the second filler module.
 9. The method of claim 8, wherein in verifying the first and second unique properties, the first unique property is verified by a base loader module and the second unique property is verified by a first filler loader module.
 10. The method of claim 8 wherein in identifying the first unique property, the first unique property is verified by a base module integrated into and/or with an operating system.
 11. The method of claim 8 wherein in verifying the first and second unique properties, the unique properties are verified by authenticating digital signatures and/or digital certificates associated with the first and second filler modules.
 12. The method of claim 8 wherein in authorizing the first and second filler modules for processing, the first and second filler modules are dynamically linked with one another and an operating system before processing.
 13. The method of claim 8 wherein in verifying the first and second unique properties, the first and second unique properties are wrapped around the first and second filler modules, respectively, and wherein the unique properties and filler modules are electronically distributed as one or more data structures.
 14. The method of claim 13 wherein in verifying the first and second unique properties, the data structures are generated by a software development kit after the filler modules are manufactured.
 15. A data structure used for dynamically integrating software modules residing in a computer readable medium, the data structure comprising: one or more certificates for dynamically authenticating accesses desired by one or more holders of the certificates that desire use of the data structure; one or more policies for defining access rights and/or interaction rights of the one or more holders to one or more modules; a policy manager for dynamically enforcing the one or more policies; and the one or more modules being accessed by the one or more holders, wherein each module includes a loader module for dynamically authenticating and dynamically loading one or more of the remaining modules, and wherein each module is available for execution when loaded, and wherein each loader is independent from other remaining ones of the loaders.
 16. The data structure of claim 15, wherein the data structure is dynamically provided to an operating system for use in authenticating holders and interactions between the one or more modules.
 17. The data structure of claim 15 further comprising, one or more cryptographic engines for dynamically authenticating the one or more certificates.
 18. The data structure of claim 17 further comprising, a base module associated with each of the one or more modules for plugging into and interfacing with one or more slots of an operating system.
 19. The data structure of claim 15, wherein each certificate includes a signature, a public key, and an identifier for one of the holders.
 20. The data structure of claim 15, wherein data structure resides in volatile memory of an operating system and is used by the operating system to manage interactions and accesses of the one or more holders to the one or more modules. 